Characterization of Ca2(+)-dependent phospholipid binding, vesicle aggregation and membrane fusion by annexins
about
Dissecting the cellular functions of annexin XI using recombinant human annexin XI-specific autoantibodies cloned by phage displayAnnexin 3 is associated with cytoplasmic granules in neutrophils and monocytes and translocates to the plasma membrane in activated cellsAnnexin A4 self-association modulates general membrane protein mobility in living cells.Characterization of 14-3-3 proteins in adrenal chromaffin cells and demonstration of isoform-specific phospholipid bindingMembrane dynamics during cellular wound repair.The effect of metal binding on the structure of annexin V and implications for membrane bindingStructure of a C-terminal AHNAK peptide in a 1:2:2 complex with S100A10 and an acetylated N-terminal peptide of annexin A2Can enzymatic activity, or otherwise, be inferred from structural studies of annexin III?CEACAM1, a cell-cell adhesion molecule, directly associates with annexin II in a three-dimensional model of mammary morphogenesisCharacterization of the calcyclin (S100A6) binding site of annexin XI-A by site-directed mutagenesisRole of exosomes in immune regulationAnnexin I in fibrotic rat lung and cultured lung fibroblasts following irradiationPhospholipase C and D regulation of Src, calcium release and membrane fusion during Xenopus laevis development.Potential of Ca2+ in Mycobacterium tuberculosis H37Rv Pathogenesis and Survival.Key role of the N-terminus of chicken annexin A5 in vesicle aggregation.The calcium-binding proteins MRP8 and MRP14 form a membrane-associated heterodimer in a subset of monocytes/macrophages present in acute but absent in chronic inflammatory lesions.Downregulation of Annexin A1 is correlated with radioresistance in nasopharyngeal carcinoma.Novel organization and properties of annexin 2-membrane complexes.Proteomic study of calpeptin-induced differentiation on calpain-interacting proteins of C2C12 myoblast.Phospholipase D activity facilitates Ca2+-induced aggregation and fusion of complex liposomes.Crocidolite asbestos induces apoptosis of pleural mesothelial cells: role of reactive oxygen species and poly(ADP-ribosyl) polymeraseAsymmetric phospholipid distribution drives in vitro reconstituted SNARE-dependent membrane fusion.Annexin A1: a central player in the anti-inflammatory and neuroprotective role of microglia.Annexin II regulates multivesicular endosome biogenesis in the degradation pathway of animal cells.Morphological and proteomic analyses reveal that unsaturated guluronate oligosaccharide modulates multiple functional pathways in murine macrophage RAW264.7 cells.Human neutrophil annexin I promotes granule aggregation and modulates Ca(2+)-dependent membrane fusionHost cellular annexin II is associated with cytomegalovirus particles isolated from cultured human fibroblasts.Physical and functional interactions of SNAP-23 with annexin A2.Membrane fusion in muscle development and repair.The participation of annexin II (calpactin I) in calcium-evoked exocytosis requires protein kinase C.Adenovirus E3 protein causes constitutively internalized epidermal growth factor receptors to accumulate in a prelysosomal compartment, resulting in enhanced degradationAnnexin 5 as a potential regulator of annexin 1 phosphorylation by protein kinase C. In vitro inhibition compared with quantitative data on annexin distribution in human endothelial cells.Role of specific lipids and annexins in calcium-dependent membrane fusion.Plasma Membrane Repair in Health and DiseaseAnnexin A2 heterotetramer: structure and functionAnnexin A2 regulates β1 integrin internalization and intestinal epithelial cell migrationCeramide 1-phosphate mediates endothelial cell invasion via the annexin a2-p11 heterotetrameric protein complex.A peptide against the N-terminus of myristoylated alanine-rich C kinase substrate inhibits degranulation of human leukocytes in vitro.Asbestos induces apoptosis of human and rabbit pleural mesothelial cells via reactive oxygen species.The annexins: spatial and temporal coordination of signaling events during cellular stress.
P2860
18941f41ed2b3f06824a4064dd0322fec5bed5e8400bbce3cfa2e0f2b311453d6c9d116708fd64ed4efc6539c1598e199ee9aeb5d9d1ed2dc00099185cad9a2f9a0bfe80f9008cf4a244ae1443b6516a6aa6f3d0c159c2a32780b9fbf035491a80693225aae5a8a487766d02215aeb5cc8ecc5e11594fe81b321ee565b29ff07915b948189b4a569800182b8bad730bcdef4475f701b9b990094bf70e2bd32d1bd792cb9e9d9e153690ba20bf95c6dd05bd15430be58f0a8a2f5b2b02b2755757d549892208966e1beba821e7033fff50a8e411260b23634bce2da42d6cd1e2b7abcbb25c8fca7d06a20d0bd796a1b6f
P248
Q24305143-C0A2FD80-8B78-4048-A316-8843F8861B3EQ24306369-48F2A5EC-CED0-4659-8D24-DDD70EA247E5Q24336949-61C6D9D3-2B75-41D6-AB0A-6060870493E8Q24528262-F8B7D184-4ED1-4395-9E40-0FD2109334FFQ27304736-75E62E4F-D04B-4661-AFFA-5844F9C9AC30Q27642177-25F610E1-617C-4C71-B18D-3E375D46F4E0Q27675650-C80D4633-CC56-46A4-9777-2C7E269ACCF9Q27736222-2A2B9A48-0756-4A27-AEBE-568485A0EE4DQ28118504-6D3087BC-C07C-48E4-8649-C299411D7E8EQ28137755-AEE8B928-298C-429A-8F9E-6B1A4E6EC3B8Q28248090-29F1FEB1-6D8E-454B-9104-A339E7B5422CQ28576017-21D29AFB-D5EA-40AA-949A-46C7CB7FEB36Q30009210-CD477354-8429-4C00-A99C-F27C03DA60D3Q30245143-C99084CD-D0F2-4651-9446-E5748C5526E1Q30376390-A2DB82CF-9479-4F0B-A24D-C12E9FA1F833Q31170766-6C428637-A11E-43C1-807E-6DD8799B088CQ32183044-EBC4AF33-473E-424E-BBF5-4CF2B3AA7B9BQ33196331-9908770D-8BBE-4F3F-B00C-50B8A1568BC3Q34136912-EC61804E-AFC1-4127-A0FC-E2FAE3C5AF51Q34425266-2961E096-AE58-40B7-A8C5-D0971951E50FQ34639511-579AC885-E09D-4781-A5B5-1CB77669F7A1Q35075467-DA39204A-70B8-4FB5-BDBB-7D922031663BQ35132315-D049E71A-BE17-4F24-84E3-2D7E0E9FF015Q35160402-3C2BCCDD-2EB7-495A-A078-9C7CEAAD2F3BQ35548822-E0145760-5CE8-4AC8-A9B1-F7252D06A507Q35605404-4674F8D1-E62E-49AE-B2B0-8E15935CA06DQ35844376-18BCB149-9D55-442D-BA82-B23832FB96C4Q36330677-F58D5BE1-485A-4F24-8CED-6C1FCDBC50A6Q36372961-D5BA9B20-105E-44BD-AE8A-D06B5720CF8BQ36530258-B12C2D7A-0D17-4A40-B3FB-C8239A0656BFQ36654255-D8927E85-70F7-4ED0-9682-DA3AE208CA15Q36763694-61EDD383-6817-49A9-8670-1EC749E75301Q36784508-BCBC05D6-4C69-42B5-93A0-4ADDEBDAF4BCQ36785977-6AB15BCC-6F30-40CE-8466-9E37421D14F2Q36790362-C883A1B2-E9BD-47EA-881B-BE52F9F5CC60Q36873692-AD41DEBF-DEB5-4280-8881-CA7C4F44A6E7Q37000587-837E29ED-89E8-43AC-BF02-44797F5817B3Q37101145-F79F3F7E-6DB3-4162-A88E-3D066709BB32Q37361129-B272B5E1-CAD5-4DEA-B6A7-9CD875792BDCQ37452818-61542376-F27C-4792-A317-8A2BC02FD32B
P2860
Characterization of Ca2(+)-dependent phospholipid binding, vesicle aggregation and membrane fusion by annexins
description
1990 nî lūn-bûn
@nan
1990 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
1990 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
1990年の論文
@ja
1990年論文
@yue
1990年論文
@zh-hant
1990年論文
@zh-hk
1990年論文
@zh-mo
1990年論文
@zh-tw
1990年论文
@wuu
name
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@ast
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en-gb
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@nl
type
label
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@ast
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en-gb
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@nl
prefLabel
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@ast
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en-gb
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@nl
P2860
P921
P3181
P356
P1433
P1476
Characterization of Ca2(+)-dep ...... nd membrane fusion by annexins
@en
P2093
R A Blackwood
P2860
P304
P3181
P356
10.1042/BJ2660195
P407
P577
1990-02-15T00:00:00Z